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TWI755056B - Preparation of nanostructured mixed lithium zirconium oxides by means of spray pyrolysis - Google Patents

Preparation of nanostructured mixed lithium zirconium oxides by means of spray pyrolysis Download PDF

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TWI755056B
TWI755056B TW109130915A TW109130915A TWI755056B TW I755056 B TWI755056 B TW I755056B TW 109130915 A TW109130915 A TW 109130915A TW 109130915 A TW109130915 A TW 109130915A TW I755056 B TWI755056 B TW I755056B
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lithium
mixed oxide
zirconium
metal
mixed
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TW202118123A (en
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德杜 雪佛
亞密 威根
哈瑞德 艾夫
高田令
法蘭茲 史契特
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德商贏創運營有限公司
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Abstract

The invention relates to a process for producing mixed oxides comprising lithium, zirconium and optionally at least one other than Li and Zr metal, by means of flame spray pyrolysis, mixed oxides obtainable by this process and their use in lithium ion batteries.

Description

藉由噴霧熱解製備奈米結構的混合鋰鋯氧化物Preparation of nanostructured mixed lithium zirconium oxides by spray pyrolysis

本發明係關於一種藉由火焰噴霧熱解製造含有鋰和鋯以及視情況選用之異於Li和Zr金屬之至少一者的混合氧化物之方法,可藉由此方法獲得之混合氧化物和其在鋰離子電池中作為活性正電極材料的用途。.The present invention relates to a method for producing, by flame spray pyrolysis, a mixed oxide containing lithium and zirconium and optionally at least one of metals other than Li and Zr, the mixed oxide obtainable by this method and the same Use as an active positive electrode material in lithium-ion batteries. .

二次鋰離子電池為目前所用最重要的電池類型之一。該二次鋰離子電池通常係由碳材料或鋰金屬合金製成之陽極、鋰金屬氧化物製成之陰極、鋰鹽溶於有機溶劑中之電解質和隔離膜所構成,該隔離膜係在該充電和該放電過程中提供鋰離子在該正電極與該負極之間的通道。Secondary lithium-ion batteries are one of the most important types of batteries in use today. The secondary lithium ion battery is usually composed of an anode made of carbon material or lithium metal alloy, a cathode made of lithium metal oxide, an electrolyte of lithium salt dissolved in an organic solvent, and a separator, the separator being on the Passage of lithium ions between the positive electrode and the negative electrode is provided during charging and the discharging.

為了努力開發具有改良之本質安全性和能量密度的二次電池,近期使用固態取代液態電解質已有顯著進展。在此類系統中,咸信具有由鋰金屬或鋰金屬合金所製成之電極的二次鋰電池提供高能量密度並且特別合適。此類全固態二次鋰離子電池在電極活性材料與電解質之間的界面處應具有良好離子導電率以便具有所需負載特徵。如JP 4982866 B2中所述般,此高離子導電率可藉由以若干含鋰化合物,諸如LiTi2 (PO4 )3 塗布活性電極材料之表面而實現。In an effort to develop secondary batteries with improved intrinsic safety and energy density, there has been significant recent progress in replacing liquid electrolytes with solids. In such systems, secondary lithium batteries with electrodes made of lithium metal or lithium metal alloys are believed to provide high energy density and are particularly suitable. Such all-solid-state secondary lithium-ion batteries should have good ionic conductivity at the interface between the electrode active material and the electrolyte in order to have the desired loading characteristics. As described in JP 4982866 B2, this high ionic conductivity can be achieved by coating the surface of the active electrode material with several lithium-containing compounds, such as LiTi 2 (PO 4 ) 3 .

含鋰之混合氧化物在固態和液態鋰離子電池中找到各種不同的應用。Lithium-containing mixed oxides find various applications in solid-state and liquid-state lithium-ion batteries.

因此,在Agnew. Chem.國際版2007,46,第1-5頁中已報導具有組成Li7 La3 Zr2 O12 (LLZ)和石榴石型結構之混合氧化物具有優異的鋰電阻,並可用作全固態鋰二次電池中之固態電解質。Therefore, it has been reported in Agnew. Chem. International Edition 2007, 46, pp. 1-5 that the mixed oxide having the composition Li 7 La 3 Zr 2 O 12 (LLZ) and a garnet-type structure has excellent lithium resistance, and Can be used as solid electrolyte in all-solid-state lithium secondary batteries.

EP 2159867 A1描述用於固態電解質之摻雜鋁的改良LLZ材料之製備。因此,碳酸鋰、氫氧化鑭和氧化鋯係混合在一起並在900-1125℃下煅燒。然後將Al2 O3 加入該經煅燒之LLZ材料中,隨後在1180℃下進行第二煅燒以獲得密度為約4克/立方厘米之經Al摻雜的LLZ氧化物。EP 2159867 A1 describes the preparation of aluminium doped modified LLZ materials for solid state electrolytes. Therefore, lithium carbonate, lanthanum hydroxide and zirconia are mixed together and calcined at 900-1125°C. Al 2 O 3 was then added to the calcined LLZ material, followed by a second calcination at 1180° C. to obtain an Al-doped LLZ oxide with a density of about 4 g/cm 3 .

亦報導類似混合氧化物以用作二次鋰電池之電極的塗層材料。Similar mixed oxides have also been reported as coating materials for electrodes of secondary lithium batteries.

鋰電池之陰極材料的普遍問題之一為其快速老化並因此在循環期間喪失性能。已知以若干金屬氧化物塗布或摻雜混合鋰過渡金屬氧化物粒子可抑制該電解質與該電極材料之不需要的反應,並因此改善該鋰離子電池之長壽命穩定性。One of the common problems with cathode materials for lithium batteries is that they age rapidly and thus lose performance during cycling. Coating or doping mixed lithium transition metal oxide particles with several metal oxides is known to suppress unwanted reactions of the electrolyte with the electrode material and thus improve the long-life stability of the lithium ion battery.

在其他金屬氧化物中,為此目的曾報導含鋯之混合氧化物。Among other metal oxides, zirconium-containing mixed oxides have been reported for this purpose.

US2017179544A揭露經摻雜基於鋯之混合金屬氧化物的鋰正電極材料之製備。因此,在實施例1中,Li7 La3 Zr2 Al0.07 O12.0105 係藉由混合該等金屬鹽並在1200℃下燒結該混合物10小時製得,隨後與混合鋰過渡金屬氧化物Li(Li10/75 Ni18/75 Co9/75 Mn38/75 )O2 乾混合,然後在900℃下加熱20小時以形成鋰正電極材料。由此製備程序可清楚看出僅有Li7 La3 Zr2 Al0.07 O12.0105 之大尺寸燒結粒子可用於此實施例中。US2017179544A discloses the preparation of lithium positive electrode materials doped with zirconium-based mixed metal oxides. Therefore, in Example 1, Li 7 La 3 Zr 2 Al 0.07 O 12.0105 was prepared by mixing the metal salts and sintering the mixture at 1200° C. for 10 hours, followed by mixing the lithium transition metal oxide Li (Li 10/75 Ni 18/75 Co 9/75 Mn 38/75 )O 2 was dry mixed and then heated at 900° C. for 20 hours to form the lithium positive electrode material. From this preparation procedure, it is clear that only large-sized sintered particles of Li 7 La 3 Zr 2 Al 0.07 O 12.0105 can be used in this example.

此種含鋯之相對較大金屬氧化物粒子的使用經常導致該核心陰極材料表面上之不均勻分佈和大黏聚金屬氧化物粒子,因此相較於未經摻雜或未經塗布之陰極材料,觀察到循環性能的改善很小或無改善。The use of such relatively large metal oxide particles containing zirconium often results in a non-uniform distribution and large cohesive metal oxide particles on the surface of the core cathode material, thus compared to undoped or uncoated cathode materials , little or no improvement in cycling performance was observed.

噴霧熱解為製造相對較小之金屬氧化物粒子的已知方法。Spray pyrolysis is a known method for producing relatively small metal oxide particles.

噴霧熱解和火焰噴霧熱解係用於製造簡單金屬氧化物以及複雜混合金屬氧化物之已建立方法。在噴霧熱解中,將呈細小液滴形式之金屬化合物引入高溫區中,並於其中經氧化及/或水解以獲得金屬氧化物。此方法之特殊類型為火焰噴霧熱解,其中將該等液滴供應至藉由點燃燃料氣體和含氧氣體所形成之火焰中。Spray pyrolysis and flame spray pyrolysis are established methods for making simple metal oxides as well as complex mixed metal oxides. In spray pyrolysis, metal compounds in the form of fine droplets are introduced into a high temperature zone, where they are oxidized and/or hydrolyzed to obtain metal oxides. A special type of this method is flame spray pyrolysis, in which the droplets are fed into a flame formed by igniting a fuel gas and an oxygen-containing gas.

WO 2015173114 A1描述一種火焰噴霧熱解方法,其係使用包含鋰、鑭、鋯和視情況選用之其他金屬化合物MX之前驅物化合物的相應溶液作為起始物以製造含有鋰、鑭、鋯和視情況選用之其他金屬的混合氧化物粉末。建議使用該等無機化合物,諸如硝酸鹽、氯化物、溴化物,或有機化合物,諸如烷氧化物或羧酸鹽作為金屬前驅物化合物。此專利申請案之較佳具體實施態樣包括鋰、鑭、鋯和其他金屬之硝酸鹽。建議使用水、C5 -C20 烷烴、C1 -C15 烷烴羧酸及/或C1 -C15 烷醇作為金屬前驅物之溶劑,其中較佳係水和含水之溶劑混合物。在所有實施例中,水係用作金屬硝酸鹽前驅物之唯一溶劑。所得混合氧化物之BET表面積係在0.19-5.1平方米/克之範圍內變化並且平均粒徑(d50 )為約2-3微米。WO 2015173114 A1 describes a flame spray pyrolysis process using as starting materials corresponding solutions comprising lithium, lanthanum, zirconium and optionally other metal compounds MX precursor compounds to produce lithium, lanthanum, zirconium and Mixed oxide powders of other metals are selected in the case. It is suggested to use such inorganic compounds, such as nitrates, chlorides, bromides, or organic compounds, such as alkoxides or carboxylates, as metal precursor compounds. Preferred embodiments of this patent application include nitrates of lithium, lanthanum, zirconium, and other metals. It is suggested to use water, C 5 -C 20 alkanes, C 1 -C 15 alkane carboxylic acids and/or C 1 -C 15 alkanols as the solvent for the metal precursor, and a solvent mixture of water and water is preferred. In all examples, water was used as the sole solvent for the metal nitrate precursor. The BET surface area of the resulting mixed oxides was varied in the range of 0.19-5.1 m2/g and the average particle size ( d50 ) was about 2-3 microns.

J. Mater. Chem. A, 2016,第4卷,第12947-12954頁揭露藉由火焰噴霧熱解從丙酸鋰(C3-羧酸鹽)、雜氮鋁三環(alumatrane)[Al(OCH2 CH2 )3 N]、異丁酸鑭(C4-羧酸鹽)和異丁酸鋯(C4-羧酸鹽)的乙醇溶液開始製備組成為Li6.25 Al0.25 La3 Zr2 O12 並具有16平方米/克之BET表面積、90奈米之一次粒徑和約5微米之黏聚物粒徑的粉末。J. Mater. Chem. A, 2016, vol. 4, pp. 12947-12954, discloses the extraction of aluminopropionate from lithium propionate (C3-carboxylate), aluminatrane [Al(OCH] by flame spray pyrolysis. 2 CH 2 ) 3 N], lanthanum isobutyrate (C4-carboxylate) and zirconium isobutyrate (C4-carboxylate) in ethanol were prepared starting with composition Li 6.25 Al 0.25 La 3 Zr 2 O 12 with Powder with a BET surface area of 16 m2/g, a primary particle size of 90 nm and a cohesive particle size of about 5 microns.

問題與解決方法Problems and Solutions

現有技術所引用之文獻教導藉由噴霧熱解製造該混合鋰鋯金屬氧化物。然而,據報導所得產物具有相對較大之粒徑,低BET表面積,並且通常具有相對較高之密度。The literature cited in the prior art teaches the manufacture of the mixed lithium zirconium metal oxide by spray pyrolysis. However, the resulting products are reported to have relatively large particle sizes, low BET surface areas, and generally have relatively high densities.

本發明所解決之問題係提供一種製造可用於二次鋰離子電池,例如作為固態電解質之組分或電極材料之組分的混合鋰鋯金屬氧化物之改良方法。The problem solved by the present invention is to provide an improved method for the manufacture of mixed lithium zirconium metal oxides that can be used in secondary lithium ion batteries, eg as a component of solid electrolytes or as a component of electrode materials.

具體而言,此方法應提供具有相對較小之粒徑、高BET表面積和低夯實密度(tamped density)之金屬氧化物粒子。Specifically, this method should provide metal oxide particles with relatively small particle size, high BET surface area, and low tamped density.

在整個實驗過程中,令人驚訝地發現當使用金屬前驅物與溶劑之特殊組合時,具有所需粒子性質之鋰鋯混合氧化物可藉由該火焰噴霧熱解方法製得。Throughout the experiments, it was surprisingly found that lithium zirconium mixed oxides with desired particle properties can be prepared by the flame spray pyrolysis method when using a specific combination of metal precursors and solvents.

製造混合氧化物之方法Method for making mixed oxides

本發明提供一種藉由火焰噴霧熱解並視情況進一步熱處理製造含有鋰、鋯和視情況選用之異於Li和Zr金屬之至少一者的混合氧化物之方法,其特徵在於在該方法中係使用至少一種金屬前驅物溶液,該溶液包含 - 羧酸鋰及/或羧酸鋯,其中此等金屬羧酸鹽中之各者包含5至20個碳原子,和 - 含有醇和含有5至20個碳原子之羧酸的溶劑混合物,其中該溶劑混合物包含低於10重量%之水,並且其中該醇相對於該羧酸之莫耳比為介於1:20和20:1之間。The present invention provides a method for producing mixed oxides containing lithium, zirconium and optionally at least one of metals other than Li and Zr by flame spray pyrolysis and optionally further heat treatment, characterized in that in the method, a using at least one metal precursor solution comprising - lithium carboxylates and/or zirconium carboxylates, wherein each of these metal carboxylates contains from 5 to 20 carbon atoms, and - a solvent mixture containing an alcohol and a carboxylic acid containing 5 to 20 carbon atoms, wherein the solvent mixture contains less than 10% by weight of water, and wherein the molar ratio of the alcohol to the carboxylic acid is between 1:20 and Between 20:1.

在火焰噴霧熱解過程中,將呈細小液滴形式之金屬化合物(金屬前驅物)溶液引入火焰中,該火焰係藉由點燃燃料氣體和含氧氣體所形成,其中該等所用金屬前驅物係經氧化及/或水解以獲得該相應金屬氧化物。During flame spray pyrolysis, a solution of metal compounds (metal precursors) in the form of fine droplets is introduced into a flame formed by igniting a fuel gas and an oxygen-containing gas, wherein the metal precursors used are Oxidation and/or hydrolysis are carried out to obtain the corresponding metal oxides.

此反應最初形成高度分散近似球形的原金屬氧化物粒子,其在進一步反應過程中聚結而形成聚集體。該等聚集體然後可聚集成黏聚物。相較於通常可藉由能量的引入而相對容易地分離成聚集體的黏聚物,該等聚集體若有也僅藉由密集引入能量就可進一步分解。This reaction initially forms highly dispersed approximately spherical primary metal oxide particles that coalesce to form aggregates during further reaction. These aggregates can then aggregate into cohesives. Such aggregates, if any, can be further decomposed only by intensive introduction of energy, compared to cohesive aggregates, which can usually be separated into aggregates relatively easily by the introduction of energy.

該產生之金屬氧化物係稱為“煙霧(fumed)”或“熱解產生的”金屬氧化物。The resulting metal oxides are referred to as "fumed" or "pyrolytically produced" metal oxides.

該火焰噴霧熱解方法一般描述於WO 2015173114 A1和其他文獻中。This flame spray pyrolysis method is generally described in WO 2015173114 A1 and other references.

該火焰噴霧熱解較佳係包括下列步驟: a) 至少一種金屬前驅物溶液係藉由霧化器氣體霧化以提供氣溶膠, b) 使該氣溶膠在該反應器之反應空間中與藉由點燃燃料氣體與含氧氣體之混合物所獲得之火焰反應以獲得反應流, c) 使該反應流冷卻並 d) 該固態金屬氧化物隨後自該反應流中去除。The preferred flame spray pyrolysis system comprises the following steps: a) at least one metal precursor solution is atomized by an atomizer gas to provide an aerosol, b) reacting the aerosol in the reaction space of the reactor with a flame obtained by igniting a mixture of fuel gas and oxygen-containing gas to obtain a reaction stream, c) cooling the reaction stream and d) The solid metal oxide is subsequently removed from the reaction stream.

燃料氣體之實施例為氫氣、甲烷、乙烷、天然氣及/或一氧化碳。特佳係使用氫氣。燃料氣體係特別用於期望產生高結晶性之金屬氧化物的具體實施態樣中。Examples of fuel gases are hydrogen, methane, ethane, natural gas and/or carbon monoxide. Specialty uses hydrogen. The fuel gas system is particularly useful in embodiments where it is desired to produce highly crystalline metal oxides.

該含氧氣體通常為空氣或富含氧之空氣。含氧氣體係特別用於期望產生(例如)高BET表面積之金屬氧化物的具體實施態樣中。該氧氣之總量通常係經選擇以使其至少足以完全轉化該燃料氣體和該等金屬前驅物。The oxygen-containing gas is usually air or oxygen-enriched air. Oxygen-containing systems are particularly useful in embodiments where it is desired to produce metal oxides with, for example, high BET surface areas. The total amount of oxygen is typically selected to be at least sufficient to completely convert the fuel gas and the metal precursors.

為了獲得該氣溶膠,該含有金屬前驅物之汽化溶液可與霧化器氣體(諸如氮氣、空氣及/或其他氣體)混合。該所得氣溶膠之細小液滴的平均液滴尺寸較佳為1-120微米,特佳為30-100微米。該等液滴通常係使用單材料或多材料噴嘴產生。為了增加該等金屬前驅物的溶解度並獲得適合該溶液霧化之黏度,可加熱該溶液。To obtain the aerosol, the vaporized solution containing the metal precursor can be mixed with an atomizer gas such as nitrogen, air and/or other gases. The average droplet size of the fine droplets of the obtained aerosol is preferably 1-120 μm, particularly preferably 30-100 μm. These droplets are typically produced using single- or multi-material nozzles. In order to increase the solubility of the metal precursors and obtain a viscosity suitable for atomization of the solution, the solution can be heated.

在本發明方法中所使用之金屬前驅物包含至少一種羧酸鋰和至少一種羧酸鋯,其各包含5至20個碳原子。The metal precursors used in the method of the present invention comprise at least one lithium carboxylate and at least one zirconium carboxylate, each comprising 5 to 20 carbon atoms.

在根據本發明方法中所使用之羧酸鋰和羧酸鋯可彼此獨立地為鋰及/或鋯之線性、分枝或環狀戊酸鹽(C5)、己酸鹽(C6)、庚酸鹽(C7)、辛酸鹽(C8)、壬酸鹽(C9)、癸酸鹽(C10)、十一酸鹽(C11)、十二酸鹽(C12)、十三酸鹽(C13)、十四酸鹽(C14)、十五酸鹽(C15)、十六酸鹽(C16)、十七酸鹽(C17)、十八酸鹽(C18)、十九酸鹽(C19)、二十酸鹽(C20)及其混合物。The lithium and zirconium carboxylates used in the process according to the invention can independently of one another be linear, branched or cyclic valerate (C5), hexanoate (C6), heptanoic acid of lithium and/or zirconium Salt (C7), Octanoate (C8), Nonanoate (C9), Decanoate (C10), Undecanoate (C11), Dodecanoate (C12), Tridecanoate (C13), Decamate Tetra salt (C14), pentadecanoate (C15), hexadecanoate (C16), heptadecanoate (C17), octadecanoate (C18), nonadecanate (C19), eicosate Salt (C20) and mixtures thereof.

最佳係使用2-乙基己酸鋯(C8)和新癸酸鋰(C10)。The best systems use zirconium 2-ethylhexanoate (C8) and lithium neodecanoate (C10).

所使用之金屬前驅物可包含異於鋰和鋯金屬之羧酸鹽。The metal precursors used may comprise carboxylates other than lithium and zirconium metals.

異於鋰和鋯金屬前驅物之彼等者亦可為無機金屬化合物,諸如硝酸鹽、氯化物、溴化物,或其他有機金屬化合物,諸如烷氧化物,例如乙氧化物、正丙氧化物、異丙氧化物、正丁氧化物及/或三級丁氧化物。Those other than lithium and zirconium metal precursors can also be inorganic metal compounds, such as nitrates, chlorides, bromides, or other organometallic compounds, such as alkoxides, such as ethoxides, n-propoxides, Isopropoxide, n-butoxide and/or tertiary butoxide.

在該混合氧化物中視情況所含之異於Li和Zr金屬之至少一者較佳可選自Na、K、Be、Mg、Ca、Sr、Ba、Zn、Co、Ni、Cu、Mn、B、Al、Ga、In、Fe、Sc、Y、La、Ti、Zr、Hf、Ce、Si、Ge、Sn、Pb、V、Nb、Ta、Mo、W及其組合。在本發明上下文中,二氧化矽和硼被視為金屬,並且其化合物亦可用作本發明方法中之該金屬前驅物。該本發明混合氧化物較佳包含鑭(La)和鋁(Al)。Preferably at least one of metals other than Li and Zr contained in the mixed oxide may be selected from Na, K, Be, Mg, Ca, Sr, Ba, Zn, Co, Ni, Cu, Mn, B , Al, Ga, In, Fe, Sc, Y, La, Ti, Zr, Hf, Ce, Si, Ge, Sn, Pb, V, Nb, Ta, Mo, W and combinations thereof. In the context of the present invention, silicon dioxide and boron are regarded as metals, and their compounds can also be used as the metal precursors in the method of the present invention. The inventive mixed oxide preferably comprises lanthanum (La) and aluminum (Al).

用於本發明方法中以溶解該等金屬前驅物之溶劑混合物包括醇和含有5至20個碳原子之羧酸。The solvent mixture used in the process of the present invention to dissolve the metal precursors includes alcohols and carboxylic acids containing from 5 to 20 carbon atoms.

該醇較佳係選自由甲醇、乙醇、正丙醇、異丙醇、正丁醇、二級丁醇、三級丁醇、正戊醇、正己醇、環己醇、正辛醇、2-乙基己醇、正癸醇、新癸醇及其混合物組成之群組。The alcohol is preferably selected from methanol, ethanol, n-propanol, isopropanol, n-butanol, secondary butanol, tertiary butanol, n-pentanol, n-hexanol, cyclohexanol, n-octanol, 2- The group consisting of ethylhexanol, n-decanol, neodecanol and mixtures thereof.

該羧酸較佳係選自由直鏈、分枝或環狀戊酸(C5)、己酸(C6)、庚酸(C7)、辛酸(C8)、壬酸(C9)、癸酸(C10)、十一酸(C11)、十二酸(C12)、十三酸(C13)、十四酸(C14)、十五酸(C15)、十六酸(C16)、十七酸(C17)、十八酸(C18)、十九酸(C19)、二十酸(C20)及其混合物組成之群組。The carboxylic acid is preferably selected from linear, branched or cyclic valeric acid (C5), hexanoic acid (C6), heptanoic acid (C7), octanoic acid (C8), nonanoic acid (C9), capric acid (C10) , Undecanoic acid (C11), dodecanoic acid (C12), tridecanoic acid (C13), tetradecanoic acid (C14), pentadecanoic acid (C15), hexadecanoic acid (C16), heptadecanoic acid (C17), The group consisting of octadecanoic acid (C18), nonadecanic acid (C19), eicosic acid (C20) and mixtures thereof.

在本發明所使用之溶劑混合物中該醇相對於該羧酸之莫耳比為介於1:20和20:1之間,較佳係介於1:15和15:1之間,更較係介於1:10和10:1之間,最佳係介於1:6和6:1之間。The molar ratio of the alcohol to the carboxylic acid in the solvent mixture used in the present invention is between 1:20 and 20:1, preferably between 1:15 and 15:1, more preferably The tie is between 1:10 and 10:1, and the best tie is between 1:6 and 6:1.

本發明所使用之溶劑混合物包含低於10重量%之水,較佳係低於5重量%之水,更佳係低於3重量%之水,甚至更佳係低於2重量%之水,再更佳係低於1重量%之水。The solvent mixture used in the present invention contains less than 10% by weight water, preferably less than 5% by weight water, more preferably less than 3% by weight water, even more preferably less than 2% by weight water, Even more preferred is less than 1% by weight of water.

該金屬前驅物溶液中之該總金屬含量較佳為1重量%-30重量%,更佳係2重量%-20重量%,甚至更佳係3重量%-15重量%。“總金屬含量”係被理解為在該所使用之金屬前驅物溶液中該金屬前驅物中所含之所有金屬的總重量比例。The total metal content in the metal precursor solution is preferably 1% to 30% by weight, more preferably 2% to 20% by weight, and even more preferably 3% to 15% by weight. "Total metal content" is understood as the total weight proportion of all metals contained in the metal precursor in the metal precursor solution used.

本發明方法所使用之溶劑混合物可另外包含鉗合劑,即可與金屬離子形成兩個或多個配位鍵的化合物。此類鉗合劑之實施例為(例如)二胺如乙二胺、伸乙二胺四乙酸(EDTA)、1,3二羰基化合物,諸如乙醯基丙酮和烷基乙醯基乙酸鹽。最佳係使用乙醯基丙酮作為此鉗合劑。The solvent mixture used in the method of the present invention may additionally contain chelating agents, ie compounds that form two or more coordinate bonds with metal ions. Examples of such chelating agents are, for example, diamines such as ethylenediamine, ethylenediaminetetraacetic acid (EDTA), 1,3-dicarbonyl compounds such as acetylacetone and alkylacetoxyacetates. Optimally, acetylacetone is used as this clamp compound.

觀察到在此類鉗合劑的存在下,若干金屬前驅物,例如鋯化合物在相對較長之儲存時間之後顯示較佳溶解性並且無沉澱。It was observed that in the presence of such chelating agents, several metal precursors, such as zirconium compounds, showed better solubility and no precipitation after relatively long storage times.

根據本發明金屬前驅物與該溶劑混合物之特殊組合的使用可保證該等金屬前驅物之良好溶解性並獲得該等所需金屬氧化物粒子性質,諸如小粒徑、高BET表面積和低夯實密度。The use of the specific combination of metal precursors and the solvent mixture according to the present invention ensures good solubility of the metal precursors and achieves the desired metal oxide particle properties, such as small particle size, high BET surface area and low tamped density .

本發明方法可進一步包括該混合氧化物之熱處理步驟,該混合氧化物係藉由火焰噴霧熱解所製成之包含鋰、鋯和視情況選用之異於Li和Zr金屬之至少一者。The method of the present invention may further comprise a thermal treatment step of the mixed oxide, the mixed oxide produced by flame spray pyrolysis comprising lithium, zirconium and optionally at least one of metals other than Li and Zr.

此進一步熱處理較佳係在600℃-1300℃之溫度下,更佳係在650℃-1250℃下,甚至更佳係在700℃ -1200℃下,再更佳係在750℃-1150℃下進行。This further heat treatment is preferably at a temperature of 600°C-1300°C, more preferably at 650°C-1250°C, even more preferably at 700°C-1200°C, still more preferably at 750°C-1150°C conduct.

根據本發明方法之熱處理可獲得具有理想性質,特別係該所需晶體結構之經熱處理的金屬氧化物。因此,例如Li7 La3 Zr2 O12 在約800℃至1200℃之溫度下進行熱處理可形成具有立方石榴石晶體結構,特別係適合用於鋰離子電池之固態電解質的混合金屬氧化物。Heat treatment according to the method of the present invention results in heat treated metal oxides having desirable properties, in particular the desired crystal structure. Thus, for example, heat treatment of Li 7 La 3 Zr 2 O 12 at a temperature of about 800°C to 1200°C can form a mixed metal oxide having a cubic garnet crystal structure, which is particularly suitable for solid electrolytes in lithium ion batteries.

本發明方法可包括該混合氧化物之進一步碾磨(較佳係球磨)步驟,該混合氧化物係藉由火焰噴霧熱解所製成之包含鋰、鋯和視情況選用之異於Li和Zr金屬之至少一者。The process of the present invention may comprise a further step of milling, preferably ball milling, of the mixed oxide prepared by flame spray pyrolysis comprising lithium, zirconium and optionally other than Li and Zr at least one of metals.

該球磨較佳係藉由ZrO2 球,例如直徑約為0.5毫米之ZrO2 球在適當溶劑(諸如乙醇或異丙醇)中進行。The ball milling is preferably carried out by means of ZrO 2 balls, eg ZrO 2 balls of about 0.5 mm in diameter, in a suitable solvent such as ethanol or isopropanol.

本發明方法最佳包括熱處理和球磨該經熱處理之金屬氧化物。The method of the present invention preferably includes heat treatment and ball milling of the heat treated metal oxide.

根據本發明方法之球磨程序可獲得具有理想性質,特別係所需晶體結構和特別適合用於鋰離子電池之粒徑的球磨金屬氧化物。因此,具有立方石榴石晶體結構和所需粒徑之經球磨和熱處理的Li7 La3 Zr2 O12 係特別適合用於鋰離子電池之固態電解質中。The ball milling procedure according to the method of the present invention yields ball milled metal oxides having desirable properties, in particular the desired crystal structure and particle size particularly suitable for use in lithium ion batteries. Therefore, the ball-milled and heat-treated Li 7 La 3 Zr 2 O 12 system with a cubic garnet crystal structure and desired particle size is particularly suitable for use in solid electrolytes for lithium ion batteries.

混合氧化物mixed oxide

藉由根據本發明方法所製得之混合氧化物的BET表面積較佳為0.1平方米/克-100平方米/克。The BET surface area of the mixed oxides prepared by the method according to the invention is preferably 0.1 m2/g to 100 m2/g.

該未經熱處理之混合氧化物(即尚未使用進一步熱處理之本發明方法的產物)的BET表面積較佳為5平方米/克-100平方米/克,更佳係7平方米/克-70平方米/克,最佳係15平方米/克-50平方米/克。The BET surface area of the unheat-treated mixed oxide (ie, the product of the method of the invention without further heat treatment) is preferably 5 m2/g to 100 m2/g, more preferably 7 m2/g to 70 m2 m/g, the best line is 15m2/g-50m2/g.

該經熱處理之混合氧化物(即已使用進一步熱處理之本發明方法的產物)的BET表面積較佳係小於10平方米/克,更佳係0.1平方米/克-10平方米/克,更佳係0.2平方米/克-5平方米/克,最佳係0.3平方米/克-3平方米/克。The BET surface area of the heat-treated mixed oxide (ie, the product of the method of the invention that has been subjected to further heat treatment) is preferably less than 10 m2/g, more preferably 0.1 m2/g to 10 m2/g, more preferably Department of 0.2 square meters / g - 5 square meters / g, the best system is 0.3 square meters / g - 3 square meters / g.

已使用進一步熱處理和球磨程序之該經熱處理和球磨的混合氧化物(即本發明方法之產物)的BET表面積較佳為3平方米/克-30平方米/克,更佳係4平方米/克-25平方米/克,最佳係5平方米/克-20平方米/克。The BET surface area of the heat-treated and ball-milled mixed oxide (i.e. the product of the process of the present invention) that has been subjected to a further heat-treatment and ball-milling procedure is preferably 3 m2/g to 30 m2/g, more preferably 4 m2/g gram-25 square meters/gram, the best line is 5 square meters/gram-20 square meters/gram.

該BET表面積可根據DIN 9277:2014藉由根據Brunauer-Emmett-Teller程序進行之氮吸附所測得。The BET surface area can be determined according to DIN 9277:2014 by nitrogen adsorption according to the Brunauer-Emmett-Teller procedure.

藉由根據本發明方法所製得之混合氧化物通常係呈聚集原粒子形式,該原粒子之數值平均直徑為5-100奈米,較佳係7-70奈米,更佳係10-50奈米,如藉由穿透式電子顯微鏡(TEM)所測得。此數值平均直徑可藉由計算以TEM分析之至少500個粒子的平均尺寸所測得。The mixed oxides obtained by the method according to the invention are usually in the form of aggregated primary particles, the primary particles having a numerical average diameter of 5-100 nm, preferably 7-70 nm, more preferably 10-50 nm Nanometers, as measured by Transmission Electron Microscopy (TEM). This numerical mean diameter can be determined by calculating the mean size of at least 500 particles analyzed by TEM.

該(聚集和黏聚)混合氧化物之數值平均粒徑d50 通常為約0.05微米-3微米,更佳係0.1微米-2微米,甚至更佳係0.15微米-1.0微米。此數值平均直徑可在合適的分散液中,例如在水性分散液中藉由靜態光散射(SLS)方法測得。The (aggregated and agglomerated) mixed oxide typically has a numerical average particle size d50 of about 0.05 microns to 3 microns, more preferably 0.1 microns to 2 microns, and even more preferably 0.15 microns to 1.0 microns. This numerical mean diameter can be determined by static light scattering (SLS) methods in suitable dispersions, eg in aqueous dispersions.

該黏聚物和部分聚集體可(例如)藉由碾磨或超音波處理該等粒子以導致具有較小粒徑和較窄粒徑分佈的粒子而破壞之。The agglomerates and partial aggregates can be disrupted, for example, by milling or sonicating the particles to result in particles having a smaller particle size and a narrower particle size distribution.

該混合氧化物之平均粒徑d50 較佳為10-150奈米,更佳係20-130奈米,甚至更佳係30-120奈米,如在25℃下經超音波處理混合物300秒之後藉由靜態光散射(SLS)所測得,該混合物係由5重量%之粒子和95重量%之0.5克/公升焦磷酸鈉水溶液組成。The average particle size d50 of the mixed oxide is preferably 10-150 nm, more preferably 20-130 nm, even more preferably 30-120 nm, eg, the mixture is sonicated at 25°C for 300 seconds The mixture consisted of 5 wt % of particles and 95 wt % of 0.5 g/liter sodium pyrophosphate aqueous solution as determined by static light scattering (SLS).

該二氧化鋯及/或含鋯之混合氧化物之粒子的跨距(d90 -d10 )/d50 較佳為0.4-1.2,更佳係0.5-1.1,甚至更佳係0.6-1.0,如在25℃下超音波處理混合物300秒之後藉由靜態光散射(SLS)所測得,該混合物係由5重量%之粒子和95重量%之0.5克/公升焦磷酸鈉水溶液組成。The span (d 90 -d 10 )/d 50 of the zirconium dioxide and/or zirconium-containing mixed oxide particles is preferably 0.4-1.2, more preferably 0.5-1.1, even more preferably 0.6-1.0, The mixture consisted of 5 wt % particles and 95 wt % of a 0.5 g/liter sodium pyrophosphate aqueous solution as determined by static light scattering (SLS) after sonicating the mixture for 300 seconds at 25°C.

因此,藉由本發明方法所製得之混合氧化物的特徵較佳在於相對較小之粒徑和窄粒徑分佈。此有助於實現用於該鋰離子電池之活性電極材料的高質量金屬氧化物摻雜及/或塗布。Therefore, the mixed oxides produced by the process of the present invention are preferably characterized by relatively small particle sizes and narrow particle size distributions. This helps to achieve high quality metal oxide doping and/or coating for the active electrode material of the lithium ion battery.

該d值d10 、d50 和d90 通常用於特徵化既定樣品之累積粒徑分佈。例如,該d10 直徑為10%樣品的體積係由小於d10 粒子所構成之直徑,該d50 為50%樣品的體積係由小於d50 粒子所構成之直徑。該d50 亦稱為“體積中值直徑”,因其按體積均分該樣品;該d90 為90%樣品的體積係由小於d90 粒子所構成之直徑。The d-values d 10 , d 50 and d 90 are typically used to characterize the cumulative particle size distribution of a given sample. For example, the volume of the sample with a d 10 diameter of 10% is the diameter composed of particles smaller than d 10 , and the volume of the d 50 sample of 50% is composed of particles smaller than the diameter of d 50 . The d 50 is also known as the "volume median diameter" because it divides the sample equally by volume; the d 90 is the diameter at which 90% of the sample's volume consists of particles smaller than the d 90 .

藉由根據本發明方法所製得之混合氧化物的夯實密度較佳為20克/公升-1000克/公升。The tamped density of the mixed oxide produced by the method according to the invention is preferably 20 g/liter to 1000 g/liter.

藉由根據本發明方法所製得未經熱處理之混合氧化物的夯實密度較佳為20克/公升-200克/公升,更佳係30克/公升-150克/公升,甚至更佳係40克/公升-130克/公升,再更佳係50克/公升-120克/公升。The tamped density of the unheat-treated mixed oxide obtained by the method according to the invention is preferably 20 g/liter to 200 g/liter, more preferably 30 g/liter to 150 g/liter, even more preferably 40 g/L-130 g/L, and even better is 50 g/L-120 g/L.

藉由根據本發明方法所製得經熱處理之混合氧化物的夯實密度較佳為400克/公升-1000克/公升,更佳係450克/公升-800克/公升,甚至更佳係500克/公升-700克/公升。The tamped density of the heat-treated mixed oxide obtained by the method according to the invention is preferably 400 g/liter to 1000 g/liter, more preferably 450 g/liter to 800 g/liter, even more preferably 500 g /L - 700 g/L.

粉狀或粗粒粒狀材料的夯實密度可根據DIN ISO 787-11:1995“顏料和增效劑之一般測試方法--第11部分:夯實後之夯實體積和表觀密度的測定”測得。此包含在攪拌和夯實之後測量床之表觀密度。The tamped density of powdered or coarse-grained granular materials may be determined according to DIN ISO 787-11:1995 "General test methods for pigments and synergists - Part 11: Determination of tamped volume and apparent density after tamping" . This involves measuring the apparent density of the bed after stirring and tamping.

藉由本發明方法所製得之混合氧化物較佳係親水性的,在其藉由火焰噴霧熱解方法合成之後係未經任何疏水性試劑(諸如矽烷)進一步處理的。由此所製得之粒子的純度通常為至少96重量%,較佳係至少98重量%,更佳係至少99重量%,其中該100%純度係指該混合氧化物僅包含指定金屬和氧。該混合氧化物可包含呈二氧化鉿形式之鉿化合物。按ZrO2 計,二氧化鉿之比例可為1重量%至4重量%。按該混合氧化物粉末的質量計,氯化物的含量較佳係小於0.5重量%,更佳係小於0.1重量%。按該混合氧化物粉末的質量計,碳的比例較佳係小於2.0重量%,更佳係0.005重量%-1.0重量%,甚至更佳係0.01重量%-0.5重量%。The mixed oxides prepared by the method of the present invention are preferably hydrophilic and have not been further treated with any hydrophobic reagents, such as silanes, after their synthesis by flame spray pyrolysis. The particles thus produced are generally at least 96 wt% pure, preferably at least 98 wt%, more preferably at least 99 wt%, wherein the 100% purity means that the mixed oxide contains only the specified metals and oxygen. The mixed oxide may comprise a hafnium compound in the form of hafnium dioxide. The proportion of hafnium dioxide may be 1% to 4% by weight based on ZrO 2 . The chloride content is preferably less than 0.5% by weight, more preferably less than 0.1% by weight, based on the mass of the mixed oxide powder. The proportion of carbon is preferably less than 2.0% by weight, more preferably 0.005% to 1.0% by weight, even more preferably 0.01% to 0.5% by weight, based on the mass of the mixed oxide powder.

該混合氧化物較佳係通式為Lia Zrb Mc O0.5a+2b+d (I) 之化合物, 其中 1.5≤a≤15,較佳係1.8≤a≤12; 0.5≤b≤3.0,較佳係0.8≤b≤3.0; 0≤c≤5,較佳係1.5≤c≤4; 對於M=Na、K,d=0.5c; 對於M=Be、Mg、Ca、Sr、Ba、Zn、Co、Ni、Cu、Mn,d=c; 對於M=B、Al、Ga、In、Fe、Sc、Y、La,d=1.5c; 對於M=Ti、Zr、Hf、Ce、Si、Ge、Sn、Pb,d=2c; 對於M=V、Nb、Ta,d=2.5c; 對於M=Mo、W,d=3c。The mixed oxide is preferably a compound of the general formula Li a Zr b M c O 0.5a+2b+d (I), wherein 1.5≤a≤15, preferably 1.8≤a≤12; 0.5≤b≤3.0 , preferably 0.8≤b≤3.0; 0≤c≤5, preferably 1.5≤c≤4; For M=Na, K, d=0.5c; For M=Be, Mg, Ca, Sr, Ba, Zn, Co, Ni, Cu, Mn, d=c; for M=B, Al, Ga, In, Fe, Sc, Y, La, d=1.5c; for M=Ti, Zr, Hf, Ce, Si , Ge, Sn, Pb, d=2c; For M=V, Nb, Ta, d=2.5c; For M=Mo, W, d=3c.

在通式(I)中,M可為選自由Na、K、Be、Mg、Ca、Sr、Ba、Zn、Co、Ni、Cu、Mn、B、Al、Ga、In、Fe、Sc、Y、La、Ti、Zr、Hf、Ce、Si、Ge、Sn、Pb、V、Nb、Ta、Mo、W組成之群組的一或數種元素。較佳地,M=La和Al。In the general formula (I), M may be selected from Na, K, Be, Mg, Ca, Sr, Ba, Zn, Co, Ni, Cu, Mn, B, Al, Ga, In, Fe, Sc, Y , La, Ti, Zr, Hf, Ce, Si, Ge, Sn, Pb, V, Nb, Ta, Mo, W, one or several elements of the group. Preferably, M=La and Al.

本發明另外提供含有鋰、鋯和視情況選用之異於Li和Zr金屬之至少一者的混合氧化物, 其中 - 該混合氧化物係呈聚集原粒子形式, - 其BET表面積為15-50平方米/克, - 其數值平均粒徑d50 =0.1-2微米,如藉由靜態光散射(SLS)所測得,並且 - 其夯實密度為50-200克/公升。The present invention further provides mixed oxides containing lithium, zirconium and optionally at least one of metals other than Li and Zr, wherein - the mixed oxides are in the form of aggregated primary particles, - the BET surface area of which is 15-50 square meters m/g, - its numerical mean particle size d 50 =0.1-2 microns, as measured by static light scattering (SLS), and - its tamped density is 50-200 g/liter.

此種混合氧化物可藉由本發明方法製得,其中無施用任何進一步熱處理。Such mixed oxides can be prepared by the method of the invention without applying any further heat treatment.

本發明另外提供含有鋰、鋯和視情況選用之異於Li和Zr金屬之至少一者的混合氧化物,  其中 - 該混合氧化物係呈聚集原粒子形式, - 其BET表面積小於10平方米/克,較佳係0.1-10平方米/克, - 其數值平均粒徑d50 =1-50微米,如藉由靜態光散射(SLS)所測得,並且 - 其夯實密度為400-1000克/公升。The invention additionally provides mixed oxides containing lithium, zirconium and optionally at least one metal other than Li and Zr, wherein - the mixed oxides are in the form of aggregated primary particles, - the BET surface area of which is less than 10 m2/ g, preferably 0.1-10 m2/g, - its numerical mean particle size d 50 =1-50 microns, as measured by static light scattering (SLS), and - its tamped density of 400-1000 g /liter.

此種混合氧化物可藉由本發明方法製得,其中施用進一步熱處理和視情況選用之球磨程序。Such mixed oxides can be prepared by the method of the invention, wherein a further thermal treatment and optionally a ball milling procedure are applied.

本發明另外提供可藉由根據本發明方法獲得之混合氧化物。The invention additionally provides mixed oxides obtainable by the process according to the invention.

該混合氧化物在鋰離子電池中之用途Use of the mixed oxide in lithium-ion batteries

本發明另外提供根據本發明混合氧化物或可藉由本發明方法獲得之混合氧化物在鋰離子電池中的用途,特別係作為鋰離子電池之固態電解質的成分、作為液體或凝膠電解質之添加劑或作為鋰離子電池之電極的組分。The invention further provides the use of the mixed oxides according to the invention or the mixed oxides obtainable by the process of the invention in lithium ion batteries, in particular as constituents of solid state electrolytes of lithium ion batteries, as additives for liquid or gel electrolytes or As a component of electrodes in lithium-ion batteries.

本發明另外提供鋰離子電池,其包含根據本發明之混合氧化物或可藉由本發明方法獲得之混合氧化物。The invention additionally provides lithium-ion batteries comprising a mixed oxide according to the invention or a mixed oxide obtainable by the method of the invention.

除了該活性正電極(陰極)以外,本發明鋰離子電池亦可包含陽極、隔離膜和含有含鋰化合物之電解質。In addition to the active positive electrode (cathode), the lithium ion battery of the present invention may also comprise an anode, a separator, and an electrolyte containing a lithium-containing compound.

該鋰離子電池之正電極(陰極)通常包含集流器和該集流器上所形成的活性陰極材料層。The positive electrode (cathode) of the lithium ion battery typically includes a current collector and a layer of active cathode material formed on the current collector.

該集電器可為鋁箔、銅箔、鎳箔、不銹鋼箔、鈦箔、經導電金屬塗布之聚合物基材或其組合。The current collector may be aluminum foil, copper foil, nickel foil, stainless steel foil, titanium foil, conductive metal coated polymer substrate, or combinations thereof.

該活性正電極材料可包括能夠可逆地嵌入/脫出鋰離子並為本領域所熟知的材料。此類活性正電極材料可包括過渡金屬氧化物,諸如含有Ni、Co、Mn、V或其他過渡金屬以及視情況選用之鋰的混合氧化物。較佳用作活性正電極材料之混合鋰過渡金屬氧化物係選自由鋰-鈷氧化物、鋰-錳氧化物、鋰-鎳-鈷氧化物、鋰-鎳-錳-鈷氧化物、鋰-鎳-鈷-鋁氧化物、鋰-鎳-錳氧化物或其混合物組成之群組。該混合鋰過渡金屬氧化物較佳具有通式LiMO2( 其中M係選自鎳、鈷、錳中之至少一種過渡金屬;更佳係M=Co),或Nix Mny Coz (其中0.3≤x≤0.9,0≤y≤0.45,0≤z≤0.4)。The active positive electrode material may include materials that are capable of reversibly intercalating/deintercalating lithium ions and are well known in the art. Such active positive electrode materials may include transition metal oxides, such as mixed oxides containing Ni, Co, Mn, V or other transition metals and optionally lithium. Mixed lithium transition metal oxides preferably used as active positive electrode materials are selected from the group consisting of lithium-cobalt oxides, lithium-manganese oxides, lithium-nickel-cobalt oxides, lithium-nickel-manganese-cobalt oxides, lithium- The group consisting of nickel-cobalt-aluminum oxides, lithium-nickel-manganese oxides, or mixtures thereof. The mixed lithium transition metal oxide preferably has the general formula LiMO 2 ( wherein M is at least one transition metal selected from nickel, cobalt, and manganese; more preferably, M=Co), or Ni x M y Co z (where 0.3 ≤x≤0.9, 0≤y≤0.45, 0≤z≤0.4).

該鋰離子電池之陽極可包括通常用於該二次鋰離子電池中能夠可逆地嵌入/脫出鋰離子之任何合適材料。其典型實施例為含碳材料,包括結晶碳諸如板狀、薄片狀、球形或纖維狀石墨形式之天然或人造石墨;非晶形碳,諸如軟碳、硬碳、介相瀝青碳化物、焦碳(fried coke)和類似物,或其混合物。另外,鋰金屬或轉化材料(例如Si或Sn)可用作陽極活性材料。The anode of the lithium ion battery may comprise any suitable material capable of reversibly intercalating/deintercalating lithium ions commonly used in secondary lithium ion batteries. Typical examples thereof are carbonaceous materials, including crystalline carbon such as natural or artificial graphite in the form of plate, flake, spherical or fibrous graphite; amorphous carbon such as soft carbon, hard carbon, mesophase pitch carbide, coke (fried coke) and the like, or mixtures thereof. In addition, lithium metal or conversion materials such as Si or Sn can be used as the anode active material.

該鋰離子電池之電解質可呈液態、凝膠或固態形式。The electrolyte of the lithium ion battery can be in liquid, gel or solid form.

該鋰離子電池之液態電解質可包括通常用於該鋰離子電池中之任何合適的有機溶劑,諸如無水碳酸伸乙酯(EC)、碳酸二甲酯(DMC)、碳酸丙烯酯、碳酸甲乙酯、碳酸二乙酯、γ-丁內酯、二甲氧基乙烷、碳酸氟伸乙酯、碳酸乙烯基伸乙酯或其混合物。The liquid electrolyte of the lithium ion battery may include any suitable organic solvent commonly used in the lithium ion battery, such as anhydrous ethyl carbonate (EC), dimethyl carbonate (DMC), propylene carbonate, ethyl methyl carbonate , diethyl carbonate, γ-butyrolactone, dimethoxyethane, fluoroethylene carbonate, vinyl ethylene carbonate or mixtures thereof.

該等凝膠電解質包括凝膠聚合物。The gel electrolytes include gel polymers.

該鋰離子電池之固態電解質可包括氧化物,例如鋰金屬氧化物、硫化物、磷酸鹽或固態聚合物。The solid state electrolyte of the lithium ion battery may include oxides such as lithium metal oxides, sulfides, phosphates or solid polymers.

該鋰離子電池之液態或聚合物凝膠電解質通常包含鋰鹽。此類鋰鹽之實施例包括六氟磷酸鋰(LiPF6 )、雙(三氟甲磺醯基)醯亞胺鋰(LiTFSI)、雙(氟磺醯基)醯亞胺鋰(LiFSI)、過氯酸鋰(LiClO4 )、四氟硼酸鋰(LiBF4 )、Li2 SiF6 、三氟甲磺酸鋰、LiN(SO2 CF2 CF3 )2 、硝酸鋰、雙(草酸)硼酸鋰、環-二氟甲烷-1,1-雙(磺醯基)醯亞胺鋰、環-六氟丙烷-1,1-雙(磺醯基)醯亞胺鋰及其混合物。The liquid or polymer gel electrolyte of the lithium ion battery typically contains a lithium salt. Examples of such lithium salts include lithium hexafluorophosphate ( LiPF6 ), lithium bis(trifluoromethanesulfonyl)imide (LiTFSI), lithium bis(fluorosulfonyl)imide (LiFSI), lithium perchlorate (LiClO 4 ), lithium tetrafluoroborate (LiBF 4 ), Li 2 SiF 6 , lithium triflate, LiN(SO 2 CF 2 CF 3 ) 2 , lithium nitrate, lithium bis(oxalate)borate, cyclo-bis Lithium fluoromethane-1,1-bis(sulfonyl)imide, lithium cyclo-hexafluoropropane-1,1-bis(sulfonyl)imide, and mixtures thereof.

該鋰離子電池,特別是含有液態或凝膠電解質之一者亦可包含防止兩電極之間直接接觸的隔離膜,該直接接觸將導致內部短路。The lithium-ion battery, especially one containing one of a liquid or gel electrolyte, may also contain a separator to prevent direct contact between the two electrodes, which would result in an internal short circuit.

該隔離膜的材料可包括聚烯烴樹脂、氟化聚烯烴樹脂、聚酯樹脂、聚丙烯腈樹脂、纖維素樹脂、非織物或其混合物。此類材料較佳包括聚烯烴樹脂(諸如基於聚乙烯或聚丙烯之聚合物)、氟化樹脂(諸如聚二氟亞乙烯聚合物或聚四氟乙烯)、聚酯樹脂(諸如聚對苯二甲酸乙二酯和聚對苯二甲酸丁二酯)、聚丙烯腈樹脂、纖維素樹脂、非織物或其混合物。The material of the separator may include polyolefin resin, fluorinated polyolefin resin, polyester resin, polyacrylonitrile resin, cellulose resin, non-woven fabric or a mixture thereof. Such materials preferably include polyolefin resins such as polyethylene or polypropylene based polymers, fluorinated resins such as polyvinylidene fluoride polymers or polytetrafluoroethylene, polyester resins such as polyterephthalene ethylene formate and polybutylene terephthalate), polyacrylonitrile resins, cellulose resins, nonwovens or mixtures thereof.

實施例Example

BET表面積為0.30-0.60平方米/克且中粒徑d50 =10.6±2微米(藉由靜態雷射散射法所測得)之商用混合鋰鎳錳鈷氧化物粉末NMC(7-1.5-1.5)(PLB-H7型)係由Linyi Gelon LIB公司所供應。Commercial mixed lithium nickel manganese cobalt oxide powder NMC (7-1.5-1.5 μm) with BET surface area of 0.30-0.60 m2/g and median particle size d50 = 10.6±2 μm (measured by static laser scattering) ) (type PLB-H7) was supplied by Linyi Gelon LIB Company.

平均分子量為4*105 克/莫耳之商用聚環氧乙烷(PEO,獲自Sigma-Aldrich)係用於該電解質配方中。PEO係按原樣使用。在手套箱中按原樣使用獲自Kishida純度為>99%(電池級)之雙(三氟甲磺醯基)醯亞胺鋰(LiTFSI)。Commercial polyethylene oxide (PEO, available from Sigma-Aldrich) with an average molecular weight of 4 *105 g/mol was used in the electrolyte formulation. PEO is used as is. Lithium bis(trifluoromethanesulfonyl)imide (LiTFSI) obtained from Kishida with >99% purity (battery grade) was used as received in the glove box.

商用經銅箔沉積之鋰係購自Honjo Metal,該銅層的厚度為10微米,並且該鋰層的厚度為20微米。Commercial copper foil deposited lithium was purchased from Honjo Metal, the thickness of the copper layer was 10 microns, and the thickness of the lithium layer was 20 microns.

比較實施例1Comparative Example 1

(源自水性硝酸鹽前驅物之Li-La-Zr-Al混合氧化物)(Li-La-Zr-Al mixed oxide from aqueous nitrate precursor)

在持續攪拌下製備18.63公斤含有1142克LiNO3 、2839克La(NO3 )3 *6H2 O、1670克Zr(NO3 )4 (金屬含量:24重量%)和212克Al(NO3 )3 *9H2 O的水溶液,直至獲得澄清溶液。此溶液相當於組成Li7.54 La3 Zr2 Al0.26 O12.6618.63 kg were prepared under constant stirring containing 1142 g LiNO 3 , 2839 g La(NO 3 ) 3 *6H 2 O, 1670 g Zr(NO 3 ) 4 (metal content: 24 wt%) and 212 g Al(NO 3 ) 3 * 9H2O in water until a clear solution is obtained. This solution corresponds to the composition Li 7.54 La 3 Zr 2 Al 0.26 O 12.66 .

2.5公斤/小時之此溶液和15 Nm3 /h之空氣經由二組分噴嘴形成氣溶膠並將其噴入具燃燒火焰之管式反應器中。該火焰之燃燒氣體係由20 Nm3 /h之氫氣與75 Nm3 /h之空氣組成,在900℃之噴嘴下方一米處的測量點形成控制溫度。另外,使用25 Nm3 /h之二次空氣。在該反應器之後,使該反應氣體冷卻並過濾之。2.5 kg/h of this solution and 15 Nm 3 /h of air form an aerosol via a two-component nozzle and inject it into a tubular reactor with a combustion flame. The combustion gas system of the flame consisted of 20 Nm 3 /h of hydrogen and 75 Nm 3 /h of air, and the control temperature was established at a measuring point one meter below the nozzle at 900°C. In addition, secondary air of 25 Nm 3 /h was used. After the reactor, the reaction gas was cooled and filtered.

該等粒子性質係顯示於表1中,該等粒子之TEM影像係顯示於圖1A和1B中。The particle properties are shown in Table 1, and the TEM images of the particles are shown in Figures 1A and 1B.

經比較實施例1之Li-La-Zr-Al混合氧化物塗布的NMC粉末之製備:Preparation of NMC powder coated with Li-La-Zr-Al mixed oxide of Comparative Example 1:

首先使NMC粉末(99克)與1.0克(1重量%)之比較實施例1的煙霧粉末在高強度實驗室混合器(具有0.5公升混合單元之Somakon混合器MP-GL)中於500 rpm(比電功率:350瓦/公斤 NMC)下先混合1分鐘以均勻混合兩種粉末。之後,將該混合強度提高至2000 rpm(比電功率:800瓦/公斤NMC,在該混合單元中該混合工具的端速:10米/秒),並持續混合5分鐘以實現藉由比較實施例1之煙霧粉末乾塗布該等NMC粒子。First NMC powder (99 grams) and 1.0 grams (1 wt%) of the smoke powder of Comparative Example 1 were mixed in a high intensity laboratory mixer (Somakon mixer MP-GL with 0.5 liter mixing unit) at 500 rpm ( Specific power: 350W/kg NMC) for 1 minute to mix the two powders uniformly. After that, the mixing intensity was increased to 2000 rpm (specific electrical power: 800 W/kg NMC, end speed of the mixing tool in the mixing unit: 10 m/s), and the mixing was continued for 5 minutes to achieve a The smoke powder of 1 was dry coated with the NMC particles.

比較實施例2Comparative Example 2

(源自乙醇硝酸鹽前驅物之Li-La-Zr-Al混合氧化物)(Li-La-Zr-Al mixed oxide from ethanol nitrate precursor)

在持續攪拌下製備18.3公斤含有779克LiNO3 、1930克La(NO3 )3 *6H2 O、1139克Zr(NO3 )4 (金屬含量:24重量%)和146克Al(NO3 )3 *9H2 O之乙醇溶液,直至獲得澄清溶液。此溶液相當於組成Li7.54 La3 Zr2 Al0.26 O12.6618.3 kg containing 779 g LiNO 3 , 1930 g La(NO 3 ) 3 *6H 2 O, 1139 g Zr(NO 3 ) 4 (metal content: 24 wt%) and 146 g Al(NO 3 ) were prepared under constant stirring 3 * 9H2O in ethanol until a clear solution is obtained. This solution corresponds to the composition Li 7.54 La 3 Zr 2 Al 0.26 O 12.66 .

2.5公斤/小時之此溶液和15 Nm3 /h之空氣經由二組分噴嘴形成氣溶膠並將其噴入具燃燒火焰之管式反應器中。該火焰之燃燒氣體係由13.7 Nm3 /h之氫氣與75 Nm3 /h之空氣組成,在900℃之噴嘴下方一米處的測量點形成控制溫度。另外,使用25 Nm3 /h之二次空氣。在該反應器之後,使該反應氣體冷卻並過濾之。2.5 kg/h of this solution and 15 Nm 3 /h of air form an aerosol via a two-component nozzle and inject it into a tubular reactor with a combustion flame. The combustion gas system of the flame consisted of 13.7 Nm 3 /h of hydrogen and 75 Nm 3 /h of air, and the control temperature was formed at a measuring point one meter below the nozzle at 900°C. In addition, secondary air of 25 Nm 3 /h was used. After the reactor, the reaction gas was cooled and filtered.

該等粒子性質係顯示於表1中,該等粒子之TEM影像係顯示於圖2A和2B中。The particle properties are shown in Table 1 and TEM images of the particles are shown in Figures 2A and 2B.

實施例1Example 1

(Li-La-Zr-Al混合氧化物)(Li-La-Zr-Al mixed oxide)

令1320克含有12重量%呈乙基己酸鋯形式之Zr的商用溶液(Octa Solingen® Zirconium 12)與173克乙醯基丙酮混合。此溶液在持續攪拌下與2273克含有2重量%呈新癸酸鋰形式之Li的商用溶液(Borchers® Deca Lithium 2)混合。在持續攪拌下加入另一含有1125克La(NO3 )3 *6H2 O、83.3克Al(NO3 )3 *9H2 O、2660克乙醇和2660克乙基己酸(乙醇:乙基己酸之莫耳比=3.1:1,該溶劑混合物中之水量:2.7重量%)的溶液中,直至獲得澄清溶液。此溶液相當於組成Li7.54 La3 Zr2 Al0.26 O12.661320 grams of a commercial solution containing 12% by weight of Zr in the form of zirconium ethylhexanoate (Octa Solingen® Zirconium 12) were mixed with 173 grams of acetylacetone. This solution was mixed with 2273 g of a commercial solution (Borchers® Deca Lithium 2) containing 2% by weight of Li in the form of lithium neodecanoate under constant stirring. Another addition containing 1125 g La(NO 3 ) 3 *6H 2 O, 83.3 g Al(NO 3 ) 3 *9H 2 O, 2660 g ethanol and 2660 g ethylhexanoic acid (ethanol: ethylhexanoic acid) was added under constant stirring Molar ratio of acid=3.1:1, amount of water in the solvent mixture: 2.7% by weight) until a clear solution is obtained. This solution corresponds to the composition Li 7.54 La 3 Zr 2 Al 0.26 O 12.66 .

2.5公斤/小時之此溶液流和15 Nm3 /h之空氣經由二組分噴嘴形成氣溶膠並將其噴入具燃燒火焰之管式反應器中。該火焰之燃燒氣體係由12.9 Nm3 /h之氫氣與75 Nm3 /h之空氣組成,在900℃之噴嘴下方一米處的測量點形成控制溫度。另外,使用25 Nm3 /h之二次空氣。在該反應器之後,使該反應氣體冷卻並過濾之。A stream of 2.5 kg/h of this solution and 15 Nm 3 /h of air were formed into an aerosol via a two-component nozzle and injected into a tubular reactor with a combustion flame. The combustion gas system of the flame consisted of 12.9 Nm 3 /h of hydrogen and 75 Nm 3 /h of air, and the control temperature was established at a measuring point one meter below the nozzle at 900°C. In addition, secondary air of 25 Nm 3 /h was used. After the reactor, the reaction gas was cooled and filtered.

該等粒子性質係顯示於表1中,該等粒子之TEM影像係顯示於圖3A和3B中。The particle properties are shown in Table 1 and TEM images of the particles are shown in Figures 3A and 3B.

經實施例1之Li-La-Zr-Al混合氧化物塗布的NMC粉末之製備:Preparation of NMC powder coated with Li-La-Zr-Al mixed oxide of Example 1:

首先使NMC粉末(99克)與1.0克(1重量%)之實施例1的煙霧粉末在高強度實驗室混合器(具有0.5公升混合單元之Somakon混合器MP-GL)中於500 rpm(比電功率:350瓦/公斤 NMC)下混合1分鐘以均勻混合該兩種粉末。之後,將該混合強度提高至2000 rpm(比電功率:800瓦/公斤NMC,在該混合單元中該混合工具之端速:10米/秒),並持續混合5分鐘以實現藉由實施例1之煙霧粉末乾塗布該等NMC粒子。NMC powder (99 g) was first mixed with 1.0 g (1 wt%) of the aerosol powder of Example 1 in a high intensity laboratory mixer (Somakon mixer MP-GL with 0.5 liter mixing unit) at 500 rpm (ratio Electric power: 350 W/kg NMC) for 1 minute to uniformly mix the two powders. After that, the mixing intensity was increased to 2000 rpm (specific electrical power: 800 W/kg NMC, the end speed of the mixing tool in the mixing unit: 10 m/s), and the mixing was continued for 5 minutes to achieve the results obtained by Example 1 The NMC particles were dry-coated with the smoked powder.

實施例2Example 2

(經煅燒之Li-La-Zr-Al複合氧化物)(calcined Li-La-Zr-Al composite oxide)

使實施例1所獲得之混合氧化物在旋窯中於950℃下煅燒6小時。該XRD分析(圖4)顯示該產物之主要相為立方石榴石結構。The mixed oxide obtained in Example 1 was calcined in a rotary kiln at 950° C. for 6 hours. The XRD analysis (FIG. 4) shows that the main phase of the product is a cubic garnet structure.

實施例3Example 3

(經煅燒和球磨之Li-La-Zr-Al混合氧化物)(calcined and ball-milled Li-La-Zr-Al mixed oxide)

使實施例2所獲得之混合氧化物在乙醇中以直徑為0.5毫米之ZrO2 球進一步進行球磨。該XRD分析(圖4)顯示該產物之主要相仍為立方石榴石結構。The mixed oxide obtained in Example 2 was further ball-milled in ethanol with ZrO 2 spheres having a diameter of 0.5 mm. The XRD analysis (Figure 4) shows that the main phase of the product is still a cubic garnet structure.

Figure 02_image001
Figure 02_image001

藉由SEM-EDX分析經LLZO塗布之混合鋰過渡金屬氧化物Analysis of LLZO-coated mixed lithium transition metal oxides by SEM-EDX

圖5顯示La(白色)在經LLZO塗布之NMC上的SEM-EDX映射,該NMC係使用煙霧奈米LLZO(實施例1)所製得,圖6顯示經煙霧粗LLZO(比較實施例1)塗布之NMC的分析結果。圖5和6的座標軸顯示:x軸=粒徑;左y軸=體積%,右y軸=累積體積%。經煙霧奈米LLZO(實施例1)乾塗布之NMC混合氧化物顯示所有NMC粒子皆經LLZO完全並均勻覆蓋(圖5)。未檢出較大LLZO黏聚物,顯示奈米結構之煙霧奈米LLZO的良好分散性。此外,在該等NMC粒子旁未發現游離未附著的LLZO粒子,指示塗層與該基材(NMC)間之強黏著力。相較之下,圖6顯示僅有煙霧粗LLZO之細LLZO粒子附著在NMC粒子表面。該等較大LLZO粒子未分散並因此未附著、位於該等NMC粒子旁。因此,該等NMC粒子未完全被氧化鋯覆蓋。Figure 5 shows SEM-EDX mapping of La (white) on LLZO-coated NMC made using fumed nano-LLZO (Example 1) and Figure 6 shows fumed crude LLZO (Comparative Example 1) Analysis results of coated NMC. The axes of Figures 5 and 6 show: x-axis = particle size; left y-axis = volume %, right y-axis = cumulative volume %. NMC mixed oxide dry-coated with fumed nano-LLZO (Example 1) showed complete and uniform coverage of all NMC particles with LLZO (Figure 5). No larger LLZO cohesives were detected, indicating good dispersion of the nanostructured smoke nano-LLZO. In addition, no free and unattached LLZO particles were found beside the NMC particles, indicating strong adhesion between the coating and the substrate (NMC). In contrast, Figure 6 shows that only fine LLZO particles of smoky coarse LLZO are attached to the surface of NMC particles. The larger LLZO particles were undispersed and therefore unattached, next to the NMC particles. Therefore, the NMC particles were not completely covered with zirconia.

圖7顯示實施例1和比較實施例1之統計分析。La(白色)平方微米在該SEM-EDX映射中之面積分佈係藉由箱形常態圖進一步分析,並且顯示在實施例1與比較實施例1之間La(白色)分散性之明顯差異。Figure 7 shows the statistical analysis of Example 1 and Comparative Example 1. The area distribution of La (white) square microns in this SEM-EDX map was further analyzed by a box normal plot and showed a clear difference in La (white) dispersion between Example 1 and Comparative Example 1.

混成固態電解質(HSE)膜之製備Preparation of Hybrid Solid Electrolyte (HSE) Membranes

令LLZO陶瓷粉末與聚環氧乙烷(PEO)和LiTFSI混合導致無溶劑之熱壓程序,從而產生可撓性且獨立膜。根據表2製備兩組具有源自實施例2和實施例3之LLZO的複合膜。磨碎加權LLZO之HSE膜,以PEO和加權LLZO碾磨之以獲得糊狀材料,然後在100℃下隔夜退火之,在100℃下於鐵氟龍(Teflon)基材之間連續熱壓之以獲得所需厚度約110微米。Mixing the LLZO ceramic powder with polyethylene oxide (PEO) and LiTFSI resulted in a solvent-free hot pressing process, resulting in a flexible and free-standing film. Two sets of composite membranes with LLZO from Examples 2 and 3 were prepared according to Table 2. The HSE film of weighted LLZO was ground, milled with PEO and weighted LLZO to obtain a paste material, which was then annealed at 100°C overnight and continuously hot pressed between Teflon substrates at 100°C. to obtain the desired thickness of about 110 microns.

Figure 02_image003
Figure 02_image003

全固態鋰金屬電池之組件和特徵Components and Features of All-Solid-State Lithium Metal Batteries

三組全固態NMC_HSE_Li金屬電池係使用(a)無LLZO填料之PEO、(b)使用經煅燒之LLZO(實施例2)填料之PEO以及(c)使用經球磨之LLZO(實施例3)填料的PEO進行組裝。該初始阻抗係藉由電化學阻抗譜(EIS)進行分析,並且該結果係顯示於圖8中。圖9顯示此等三個電池在60℃和0.1C下介於3.0伏特和4.3伏特之間初始形成。在三個實施例中,使用實施例3之LLZO的電池在0.1C放電時顯示140毫安培-小時/克之最高電容和最低阻抗。Three sets of all-solid NMC_HSE_Li metal cells were prepared using (a) PEO without LLZO filler, (b) PEO using calcined LLZO (Example 2) filler and (c) ball-milled LLZO (Example 3) filler PEO is assembled. The initial impedance was analyzed by electrochemical impedance spectroscopy (EIS), and the results are shown in FIG. 8 . Figure 9 shows the initial formation of these three cells between 3.0 volts and 4.3 volts at 60°C and 0.1C. Of the three examples, the cell using the LLZO of Example 3 exhibited the highest capacitance and lowest impedance of 140 mA-hour/gram at 0.1C discharge.

[圖1A和1B]為如比較實施例1所述般製得之Li-La-Zr-Al混合氧化物粒子的TEM影像。 [圖2A和2B]為如比較實施例2所述般製得之Li-La-Zr-Al混合氧化物(LLZO)粒子的TEM影像。 [圖3A和3B]為如實施例1所述般製得之本發明Li-La-Zr-Al混合氧化物(LLZO)粒子的TEM影像。 [圖4]顯示如實施例1-3所述般製得之本發明Li-La-Zr-Al混合氧化物(LLZO)的XRD圖譜。 [圖5]顯示La(白色)在經LLZO塗布之NMC上的SEM-EDX映射影像,該經LLZO塗布之NMC係使用如實施例1所述般製得之LLZO製成。 [圖6]顯示La(白色)在經LLZO塗布之NMC上的SEM-EDX映射影像,該經LLZO塗布之NMC係使用如比較實施例1所述般製得之LLZO製成。 [圖7]顯示La在該經LLZO塗布之NMC的SEM-EDX映射影像中之面積分佈的統計分析,該經LLZO塗布之NMC係使用如比較實施例1和實施例1所述般製得之LLZO製成。 [圖8]顯示藉由電化學阻抗譜法(EIS)所測得具有如實施例2和3所述般製得之LLZO以及不具LLZO(PEO)之全固態鋰金屬電池的初始阻抗測試結果。 [圖9]顯示具有如實施例2和3所述般製得之LLZO以及不具LLZO(PEO)之全固態鋰金屬電池在60℃和0.1C下介於3.0伏特和4.3伏特之間初始形成的結果。1A and 1B ] are TEM images of Li-La-Zr-Al mixed oxide particles prepared as described in Comparative Example 1. 2A and 2B are TEM images of Li-La-Zr-Al mixed oxide (LLZO) particles prepared as described in Comparative Example 2. 3A and 3B are TEM images of the Li-La-Zr-Al mixed oxide (LLZO) particles of the present invention prepared as described in Example 1. [FIG. [ Fig. 4 ] shows the XRD patterns of the Li-La-Zr-Al mixed oxide (LLZO) of the present invention prepared as described in Examples 1-3. [ FIG. 5 ] shows an SEM-EDX mapping image of La (white) on LLZO-coated NMC made using LLZO prepared as described in Example 1. [ FIG. [ FIG. 6 ] shows an SEM-EDX mapping image of La (white) on LLZO-coated NMC made using LLZO prepared as described in Comparative Example 1. [ FIG. [ FIG. 7 ] A statistical analysis showing the area distribution of La in the SEM-EDX mapped image of the LLZO-coated NMC prepared as described in Comparative Example 1 and Example 1 Made of LLZO. [ FIG. 8 ] shows the initial impedance test results of all-solid-state lithium metal batteries with LLZO prepared as described in Examples 2 and 3 and without LLZO (PEO) measured by electrochemical impedance spectroscopy (EIS). [Fig. 9] shows the initial formation of all-solid-state lithium metal batteries with LLZO prepared as described in Examples 2 and 3 and without LLZO (PEO) between 3.0 volts and 4.3 volts at 60°C and 0.1C. result.

Claims (17)

一種藉由火焰噴霧熱解製造含有鋰、鋯和視情況選用之異於Li和Zr金屬之至少一者的混合氧化物之方法,其特徵在於在該方法中係使用至少一種金屬前驅物溶液,該溶液包含- 羧酸鋰及/或羧酸鋯,其中此等金屬羧酸鹽中之各者包含5至20個碳原子,和- 含有醇和具有5至20個碳原子之羧酸的溶劑混合物,其中該溶劑混合物包含低於10重量%之水,並且其中該醇相對於該羧酸之莫耳比為介於1:20和20:1之間。 A method for producing mixed oxides containing lithium, zirconium and optionally at least one of metals other than Li and Zr by flame spray pyrolysis, characterized in that at least one metal precursor solution is used in the method, The solution comprises - lithium carboxylates and/or zirconium carboxylates, wherein each of these metal carboxylates comprises 5 to 20 carbon atoms, and - a solvent mixture comprising an alcohol and a carboxylic acid having 5 to 20 carbon atoms , wherein the solvent mixture comprises less than 10% by weight of water, and wherein the molar ratio of the alcohol to the carboxylic acid is between 1:20 and 20:1. 根據請求項1之方法,其中該噴霧火焰熱解包括下列步驟:a)至少一種金屬前驅物溶液係藉由霧化器氣體霧化以提供氣溶膠,b)使該氣溶膠在該反應器之反應空間中與藉由點燃燃料氣體與含氧氣體之混合物所獲得之火焰反應以獲得反應流,c)使該反應流冷卻並d)該固態金屬氧化物隨後自該反應流中去除。 The method of claim 1, wherein the spray flame pyrolysis comprises the steps of: a) at least one metal precursor solution is atomized by an atomizer gas to provide an aerosol, b) subjecting the aerosol to the reactor The reaction space is reacted with a flame obtained by igniting a mixture of fuel gas and oxygen-containing gas to obtain a reaction stream, c) the reaction stream is cooled and d) the solid metal oxide is subsequently removed from the reaction stream. 根據請求項1或2之方法,其中該混合氧化物係通式為LiaZrbMcO0.5a+2b+d(I)之化合物,其中1.5
Figure 109130915-A0305-02-0029-1
a
Figure 109130915-A0305-02-0029-2
15,0.5
Figure 109130915-A0305-02-0029-3
b
Figure 109130915-A0305-02-0029-4
3.0,0
Figure 109130915-A0305-02-0029-5
c
Figure 109130915-A0305-02-0029-6
5,對於M=Na、K,d=0.5c; 對於M=Be、Mg、Ca、Sr、Ba、Zn、Co、Ni、Cu、Mn,d=c;對於M=B、Al、Ga、In、Fe、Sc、Y、La,d=1.5c;對於M=Ti、Zr、Hf、Ce、Si、Ge、Sn、Pb,d=2c;對於M=V、Nb、Ta,d=2.5c;對於M=Mo、W,d=3c。
A method according to claim 1 or 2, wherein the mixed oxide is a compound of the general formula Li a Zr b M c O 0.5a+2b+d (I), wherein 1.5
Figure 109130915-A0305-02-0029-1
a
Figure 109130915-A0305-02-0029-2
15, 0.5
Figure 109130915-A0305-02-0029-3
b
Figure 109130915-A0305-02-0029-4
3.0, 0
Figure 109130915-A0305-02-0029-5
c
Figure 109130915-A0305-02-0029-6
5. For M=Na, K, d=0.5c; For M=Be, Mg, Ca, Sr, Ba, Zn, Co, Ni, Cu, Mn, d=c; For M=B, Al, Ga, In, Fe, Sc, Y, La, d=1.5c; for M=Ti, Zr, Hf, Ce, Si, Ge, Sn, Pb, d=2c; for M=V, Nb, Ta, d=2.5 c; for M=Mo, W, d=3c.
根據請求項1之方法,其中該混合氧化物之BET表面積為0.1-100平方米/克。 A method according to claim 1, wherein the mixed oxide has a BET surface area of 0.1-100 m2/g. 根據請求項1之方法,其中該羧酸鋰和羧酸鋯係彼此獨立地選自由鋰及/或鋯之線性、分枝或環狀戊酸鹽(C5)、己酸鹽(C6)、庚酸鹽(C7)、辛酸鹽(C8)、壬酸鹽(C9)、癸酸鹽(C10)、十一酸鹽(C11)、十二酸鹽(C12)、十三酸鹽(C13)、十四酸鹽(C14)、十五酸鹽(C15)、十六酸鹽(C16)、十七酸鹽(C17)、十八酸鹽(C18)、十九酸鹽(C19)、二十酸鹽(C20)及其混合物組成之群組的羧酸鹽。 The method according to claim 1, wherein the lithium and zirconium carboxylates are independently selected from the group consisting of linear, branched or cyclic valerates (C5), hexanoates (C6), heptanoates of lithium and/or zirconium. Acid (C7), Octanoate (C8), Nonanoate (C9), Decanoate (C10), Undecanoate (C11), Dodecanoate (C12), Tridecanoate (C13), Myristate (C14), pentadecanoate (C15), hexadecanoate (C16), heptadecanoate (C17), octadecanoate (C18), nonadecanate (C19), twenty Carboxylic acid salts of the group consisting of acid salts (C20) and mixtures thereof. 根據請求項1之方法,其中該醇係選自由甲醇、乙醇、正丙醇、異丙醇、正丁醇、二級丁醇、三級丁醇、正戊醇、正己醇、環己醇、正辛醇、2-乙基己醇、正癸醇、新癸醇及其混合物組成之群組。 The method according to claim 1, wherein the alcohol is selected from methanol, ethanol, n-propanol, isopropanol, n-butanol, secondary butanol, tertiary butanol, n-pentanol, n-hexanol, cyclohexanol, The group consisting of n-octanol, 2-ethylhexanol, n-decanol, neodecanol and mixtures thereof. 根據請求項1之方法,其中該金屬前驅物溶液包含選自由二胺和1,3-二羰基化合物組成之群組的鉗合劑。 The method of claim 1, wherein the metal precursor solution comprises an chelating agent selected from the group consisting of diamines and 1,3-dicarbonyl compounds. 根據請求項1之方法,其中該混合氧化物 之數值平均粒徑d50=0.05-2微米,如藉由靜態光散射(SLS)所測得。 A method according to claim 1, wherein the mixed oxide has a numerical average particle size d 50 =0.05-2 microns, as measured by static light scattering (SLS). 根據請求項1之方法,其中該混合氧化物之夯實密度(tamped density)為20-1000克/公升。 The method of claim 1, wherein the mixed oxide has a tamped density of 20-1000 grams/liter. 根據請求項1之方法,其進一步包括該混合氧化物之熱處理,該混合氧化物係藉由火焰噴霧熱解所製成之包含鋰、鋯和視情況選用之異於Li和Zr金屬之至少一者。 The method of claim 1, further comprising heat treatment of the mixed oxide, the mixed oxide produced by flame spray pyrolysis comprising lithium, zirconium, and optionally at least one of metals other than Li and Zr By. 根據請求項10之方法,其中該熱處理係在600℃-1300℃之溫度下進行。 The method according to claim 10, wherein the heat treatment is carried out at a temperature of 600°C to 1300°C. 根據請求項1之方法,其進一步包括該混合氧化物之碾磨,該混合氧化物係藉由火焰噴霧熱解所製成之包含鋰、鋯和視情況選用之異於Li和Zr金屬之至少一者。 The method of claim 1, further comprising milling the mixed oxide prepared by flame spray pyrolysis comprising lithium, zirconium, and optionally at least metals other than Li and Zr one. 根據請求項12之方法,其中該碾磨係球磨。 The method of claim 12, wherein the milling is ball milling. 一種根據請求項1之方法所製得之混合氧化物,其特徵在於該混合氧化物係呈聚集原粒子形式,其BET表面積為15-50平方米/克,其數值平均粒徑d50=0.1-2微米,如藉由靜態光散射(SLS)所測得,並且其夯實密度為30-150克/公升。 A mixed oxide obtained by the method of claim 1, characterized in that the mixed oxide is in the form of aggregated primary particles, its BET surface area is 15-50 m2/g, and its numerical average particle diameter d 50 =0.1 -2 microns, as measured by static light scattering (SLS), and have a tamped density of 30-150 grams/liter. 一種根據請求項1之方法所製得之混合 氧化物,其特徵在於該混合氧化物係呈聚集原粒子形式,其BET表面積小於10平方米/克,其數值平均粒徑d50=1-50微米,如藉由靜態光散射(SLS)所測得,並且其夯實密度為400-1000克/公升。 A mixed oxide prepared by the method of claim 1, characterized in that the mixed oxide is in the form of aggregated primary particles, its BET surface area is less than 10 m2/g, and its numerical average particle size d 50 =1-50 microns, as measured by static light scattering (SLS), and have a tamped density of 400-1000 grams/liter. 一種根據請求項14或15之混合氧化物的用途,其係作為固態電解質之成分、作為液體或凝膠電解質之添加劑或作為鋰離子電池之電極的組分。 A use of a mixed oxide according to claim 14 or 15 as a constituent of solid electrolytes, as an additive to liquid or gel electrolytes or as a constituent of electrodes for lithium-ion batteries. 一種鋰離子電池,其包含請求項14或15之混合氧化物。 A lithium ion battery comprising the mixed oxide of claim 14 or 15.
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